counterions and contain no liquid compo-
nents; thus, they are inherently not subject to
leakage or evaporation.
We prepare polyanionic and polycationic
ionoelastomers by polymerization of 1-ethyl-3-
methyl imidazolium (3-sulfopropyl) acrylate (ES)
and 1-[2-acryloyloxyethyl]-3-butylimidazolium
bis(trifluoromethane) sulfonimide (AT), respec-
tively (Fig. 1B), following modified literature
procedures ( 23 , 24 ). The low glass transition
temperatures (Tg) of these ionoelastomers enable
selective ion conduction at ambient temper-
ature by segmental motion of polymer chains
( 25 ). Lightly cross-linked ionoelastomers are
highly stretchable [up to a uniaxial stretch
ratio (lu)of2.2],compatiblewithdemandsfor
flexible and wearable devices ( 26 ). In addition,
whereas hydrogel devices rapidly lose water
in ambient conditions and are challenging
to seal, ionoelastomers are nonvolatile and
have a wide electrochemical window (±~3 V)
compared with polyelectrolyte hydrogels
(<±1 V). Detailed experimental procedures
and characterization of ionoelastomers are
described in the supplementary materials (figs.
S1 to S9).
After joining ES and AT ionoelastomers,
mobile counterions near the interface dif-
fuse into the opposite domain in a process
driven by entropy. Excess fixed polyanionic
and polycationic charges on the ES and AT
sides, respectively, are left behind. Because
the cross-linked networks do not permit
long-range motion of the fixed ions, an in-
terfacial electric field directed from AT to ES
is developed, leading to a drift current of the
mobile ions that exactly counterbalances
their diffusion current at equilibrium (fig. S10),
as described by extension of the classical
model ( 12 ) of p-n semiconductors (see sup-
plementary text for details).
The depletion of mobile ions and excess
of fixed ions provides strong electrostatic
adhesion between the two layers, such that
peeling of an ES/AT junction leads to co-
hesive failure of the layers themselves with
a toughness ofGc=400±24J/m^2 ,whereas
ES/ES and AT/AT homojunctions peel easily
along the interface withGc≈40 J/m^2 (fig.
S11). In contrast to electronic semiconductor
junctions, which typically require multistep
lithographic fabrication processes, stretch-
able and robust ES/AT junctions can be
easily prepared by attaching two preformed
ionoelastomers.
We compare ES/ES and AT/AT homo-
junctions to ES/AT heterojunctions by ac-
impedance measurements (Fig. 1, C and D).
Impedance data are described using the
equivalent circuit model in Fig. 1D ( 27 ),with fitted parameters in table S2. Capaci-
tance values for ES/ES and AT/AT homo-
junctions are 150 ± 30 and 100 ± 20mF/cm^2 ,
respectively—roughly 100 times as large as
the ~1mF/cm^2 values typical of ionic liquid
electrolytes with planar electrodes ( 27 )—owing
to the high surface areas of the carbon nano-
tube electrodes in our work. In stark contrast,
the capacitance of an ES/AT heterojunction is
0.7 ± 0.2mF/cm^2 , clearly revealing the presence
of the low-capacitance planar IDL at the
ES/AT interface.
We characterize ionic rectification by ap-
plying dc biases of opposite signs to ES/AT
heterojunctions. As shown in Fig. 2A, a
forward bias voltage (V) of +0.35 V yields
an exponential decay of current over a time
(t) of 71.0 ± 0.3 s, whereas a reverse bias of
−0.35 V leads to a 200-fold more rapid decay
(t= 0.32 ± 0.01 s). The total associated
charges (Q) by integrating these curves are
33 ± 5 and 0.7 ± 0.1mC/cm^2 , for + 0.35 V and
−0.35 V, respectively. FullQ-Vcurves of all
ionoelastomer junctions, summarized in Fig.
2B, show that ES/ES and AT/AT homo-
junctions have ideal linear capacitance
curves (C=Q/V), with respective slopes
of 220 and 170mF/cm^2 , of similar magnitude
to the values from ac impedance. On the
contrary, clear asymmetry is observed forKimet al.,Science 367 , 773–776 (2020) 14 February 2020 2of4
Fig. 2. Non-faradaic rectification by ionoelastomer diodes.(A) Current
density of an ES/AT junction under a forward bias of +0.35 V and a reverse bias
of−0.35 V, applied at 0 s. The inset shows a longer time period. (B)Q-Vcurves
for ES/ES, AT/AT, and ES/AT. Error bars indicate SDs from more than five
measurements for each point. (C) Rectification by ionoelastomer junctions under
an alternating potential of ±0.35 V at 0.05 Hz. Applied voltage is plotted on
the top; the corresponding current is shown on the bottom. (D)Nyquistplotand
(E) Bode phase plot from ac-impedance measurements of ES/AT under dc biases.
(F) Nyquist plot of ES/AT under +1 V. The equivalent circuit model for an ES/AT
junction under dc bias is shown in the inset of (F). RI, interfacial resistance.RESEARCH | REPORT